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《南京师大学报（自然科学版）》[ISSN:1001-4616/CN:32-1239/N]

Issue:

2019年03期

Page:

115-121

Research Field:

·全国机器学习会议论文专栏·

Publishing date:

Info

Title:

Image Recognition Based on Improved Deep Neural Network

Author(s):

Tang Kai; He Qing; Zhao Qun; Wang Xu

College of Big Data and Information Engineering,Guizhou University,Guizhou Provincial Key Laboratory of Public Big Data,Guiyang 550025,China

Keywords:

image classificaiton; deep learning; deep residual network; spatial transformation network

PACS:

TP183

DOI:

10.3969/j.issn.1001-4616.2019.03.015

Abstract:

With the development of big data era,deep learning has gradually become more practical,leading the development of the era of artificial intelligence. Convolution neural network plays a very important role in image recognition,and it is one of the important components of deep learning model.The key point of image recognition is how to extract the effective features of the image,so as to effectively solve the problem of image recognition. In view of this difficulty,the main work of this paper is to introduce spatial transformation network on the basis of residual network(ResNet). The spatial transformation network can effectively extract the region of interest and improve the efficiency of image recognition. At the same time for the feature extracted by Softmax classifier is not good. In many cases,the intra-class spacing is even larger than the inter-class spacing,but in the image recognition task,the expected features are not only divisible,and with require great differences. In order to solve this problem,this paper introduces the Center Loss function into the Softmax classifier. Center Loss function can make the distance between the extracted feature classes larger and the intra-class distance smaller,thus improving the recognition degree of the extracted features. In the open CIFAR10 dataset,the model has achieved good performance,and the correct recognition rate is up to 89%. Under the same experimental conditions,compared with the unmodified residual network model,the proposed model improves the recognition accuracy of open CIFAR10 dataset by 6%.

References:

[1] LECUN Y,BOTTOU L,BENGIO Y,et al. Gradient-based learning applied to document recognition[J]. Proceedings of the IEEE,1998,86(11):2278-2324.
[2]HE K,ZHANG X,REN S,et al. Deep residual learning for image recognition[C]//IEEE Conference on Computer Vision & Pattern Recognition. USA:IEEE,2016.
[3]刘万军,梁雪剑,曲海成. 自适应增强卷积神经网络图像识别[J]. 中国图象图形学报,2017,22(12):1723-1736.
[4]曾维亮,林志贤,陈永洒. 基于卷积神经网络的智能冰箱果蔬图像识别的研究[J]. 微型机与应用,2017,36(8):56-59.
[5]REN S,HE K,GIRSHICK R,et al. Faster R-CNN:towards real-time object detection with region proposal networks[J]. IEEE transactions on pattern analysis and machine intelligence,2017,39(6):1137-1149.
[6]LIU M,SHI J,LI Z,et al. Towards better analysis of deep convolutional neural networks[J]. IEEE transactions on visualization and computer graphics,2017,23(1):91-100.
[7]SILVER D,SCHRITTWIESER J,SIMONYAN K,et al. Mastering the game of go without human knowledge[J]. Nature,2017,550(7676):354.
[8]ZHU P,ISAACS J,BO F,et al. Deep learning feature extraction for target recognition and classification in underwater sonar images[C]//2017 IEEE 56th Annual Conference on Decision and Control(CDC). Melbourne,Australia:IEEE,2018.
[9]WEI W,ZHAO M,WANG J. Effective android malware detection with a hybrid model based on deep autoencoder and convolutional neural network[J]. Journal of ambient intelligence & humanized computing,2018(1):1-9.
[10]刘晨,曲长文,周强,等. 基于卷积神经网络迁移学习的SAR图像目标分类[J]. 现代雷达,2018(3):38-42.
[11]WANG Y,FEI L,ZHANG K,et al. LFNet:a novel bidirectional recurrent convolutional neural network for light-field image super-resolution[J]. IEEE transactions on image processing,2018,27(9):19-26.
[12]CHEN B,ZHANG Y,XIN P. An effective time-domain microwave image reconstruction algorithm for loss-y layered media utilizing the ADI-FDTD method[J]. Journal of China universities of posts & telecommunications,2018,25(2):93-99.
[13]MALLAHI M E,ZOUHRI A,QJIDAA H. Radial meixner moment invariants for 2D and 3D image recognition[J]. International journal of automation & computing,2018,28(2):207-216.
[14]ARCOS G A ?,?LVAREZ G A J A,SORIA M L M. Deep neural network for traffic sign recognition systems:an analysis of spatial transformers and stochastic optimisation methods[J]. Neural Netw,2018,99(12):158-165.
[15]JIN X B,XIE G S,HUANG K,et al. Discriminant zero-shot learning with center loss[J]. Cognitive computation,2019(7):1-10.
[16]曲之琳,胡晓飞. 基于改进激活函数的卷积神经网络研究[J]. 计算机技术与发展,2017(12):83-86.

Memo

Memo:

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Common functions

Last Update: 2019-09-30